JP2008309301A - Liquefied gas receiving storage device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquefied gas receiving storage device capable of lowering a liquid level of a rising part, without using a liquid draining drum and a liquid draining drum pump. <P>SOLUTION: This liquefied gas receiving storage device 10 has a storage tank 3 receiving and storing liquefied gas from a predetermined liquefied gas supply source, and a receiving pipe 5 for sending the liquefied gas into the storage tank 3 from the liquified gas supply source, and has the function of controlling the height of the liquid level of the liquefied gas remaining in the receiving pipe 5 when finishing liquefied gas reception to the storage tank 3. The receiving pipe 5 has the rising part 5a extending upward from below in the middle of extending to the storage tank 3 side. The liquid level is a liquid level of the liquefied gas remaining in this rising part 5a. Pressurized gas for making pressure act on the liquid level is supplied in the receiving pipe, and thus, the device has a liquid level pressing-down device 7 for pushing down the liquid level. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a liquefied gas receiving and storing device comprising: a storage tank for receiving and storing liquefied gas from a liquefied gas supply source such as an LNG ship tank; and a receiving pipe for sending the liquefied gas from the liquefied gas supply source to the storage tank. About. In particular, the present invention relates to a liquefied gas receiving and storing device having a function of controlling the liquid level height of the liquefied gas remaining in the receiving pipe at the end of receiving the liquefied gas into the storage tank.

  The liquefied gas receiving and storing device is, for example, an LNG receiving facility that receives and stores LNG from a tank of an LNG ship that has transported LNG (liquefied Natural Gas). The LNG receiving facility is described in Patent Document 1 below, for example. FIG. 5 is a diagram illustrating a configuration of the LNG receiving facility.

  The LNG receiving facility includes a loading arm 21, a receiving pipe 5, a storage tank 3, a return gas pipe 25, a return gas blower 27, a vaporizer 29, a gas supply pipe 13, a BOG compressor 31, and a BOG pipe 33.

  The loading arm 21 is for connecting to an LNG ship that has transported LNG. LNG in the LNG ship tank 35 is fed into the loading arm 21 by a cargo pump. The receiving pipe 5 receives the LNG of the LNG ship tank 35 through the loading arm 21. The storage tank 3 stores LNG fed from the LNG ship tank 35 through the receiving pipe 5. Note that the return gas pipe 25 and the return gas blower 27 are for returning BOG (Boil Off Gas) to the LNG ship tank 35 whose pressure has dropped when LNG is received. The vaporizer 29 generates vaporized gas from the liquefied gas supplied from the storage tank 3. The gas supply pipe 13 is for supplying the vaporized gas from the vaporizer 29 as a combustion gas (for example, city gas) to a predetermined demand point.

  If the receiving pipe 5 is left in the period until the LNG acceptance into the storage tank 3 is finished and then the next LNG is accepted, the temperature of the receiving pipe 5 rises to room temperature due to heat input to the receiving pipe 5. End up. In this case, when low-temperature LNG flows into the receiving pipe 5 at the time of the next LNG reception, the LNG evaporates and a large amount of BOG is generated. Therefore, the receiving pipe 5 is cooled during a standby period from the end of LNG reception until the next LNG reception.

One method for cooling the receiving pipe is a liquefied gas holding / replacement method. In this method, a part of the liquefied gas in the receiving pipe and the supercooled liquefied gas in the storage tank are replaced with each other at a predetermined interval in the standby period.
FIG. 6 shows a configuration for performing such a liquefied gas holding / replacement method. At the time of replacement, the on-off valve 37 is opened to send the liquefied gas to the draining drum 39, and the liquefied gas sent to the draining drum 39 is sent to the storage tank 3 by the draining drum pump 41, and the on-off valve 43 is opened to open the pump 3a. LNG supplied from the storage tank 3 is supplied to the receiving pipe 5.

  Incidentally, as shown in FIG. 6, the receiving pipe 5 often has a rising portion 5a. For example, when the side surface of the storage tank 3 is a concrete wall, the rising portion 5a of the reception pipe 5 is provided to connect the reception pipe 5 to the upper part of the storage tank 3 that is not covered by the concrete wall.

If such a rising portion 5a exists, a problem of Geisering occurs. Geisering is an abrupt phase transition oscillation phenomenon between the liquid phase and the gas phase that occurs when the liquefied gas is overheated by heat input. If Geisering occurs at the rising part 5a, if the liquid level of the rising part 5a is high, the bubbles will be lifted up and the bubbles will fall out, and then the liquid will drop, causing abnormal noise and vibration, which will damage the equipment. There is a possibility that.
In order to prevent such a Geiser ring, it is necessary to lower the liquid level of LNG remaining in the rising portion 5a at the end of LNG reception.

In order to lower the liquid level of the LNG remaining in the rising portion 5a, in FIG. 6, at the end of the LNG reception, the on-off valve 37 is opened and the liquefied gas is sent to the draining drum 39, thereby lowering the liquid level of the rising portion 5a. . The liquefied gas sent to the liquid draining drum 39 is sent to the storage tank 3 by the liquid draining drum pump 41.
JP 2001-200996 A "Liquid gas receiving pipe cooling and holding device"

  However, in the above method, in order to lower the liquid level of the rising portion 5a, the liquid draining drum 39, the liquid draining drum pump 41 and the equipment associated therewith are necessary, and the construction cost and operation cost are high. . Therefore, it is desirable that the liquid level of the rising portion 5a be lowered at the end of LNG reception without providing the liquid draining drum 39 and the liquid draining drum pump 41.

  Therefore, an object of the present invention is to provide a liquefied gas receiving and storing device capable of lowering the liquid level at the rising portion without using a liquid draining drum and a liquid draining drum pump.

To achieve the above object, according to the present invention, a storage tank that receives and stores liquefied gas from a predetermined liquefied gas supply source, and a receiving pipe for sending liquefied gas from the liquefied gas supply source to the storage tank; A liquefied gas receiving and storing device having a function of controlling the height of the liquid level of the liquefied gas remaining in the receiving pipe at the end of receiving the liquefied gas into the storage tank, wherein the receiving pipe is connected to the storage tank side. In the middle of the extension, it has a rising portion extending from the bottom to the top, and the liquid level is a liquid level of the liquefied gas remaining in the rising portion, and supplies pressurized gas that applies pressure to the liquid level into the receiving pipe. Thus, a liquefied gas receiving and storing device is provided, which includes a liquid level reducing device that pushes down the liquid level.
Preferably, the liquid level reducing device has a liquid draining pipe for connecting the receiving pipe and the storage tank so as to send the liquefied gas pushed back by the pressurized gas to the storage tank.

In the above-described configuration, the liquid level reducing device supplies pressurized gas for applying pressure to the liquid level into the receiving pipe, and thereby pushes down the liquid level, thereby eliminating the need for a liquid draining drum.
Further, since the liquefied gas pushed back by the pressurized gas is sent to the storage tank through the drain pipe, the drain drum pump is not necessary.
Therefore, the liquid level at the rising portion can be lowered without using the liquid draining drum and liquid draining drum pump. As a result, it is possible to reduce construction costs and operation costs required for the draining drum and the draining drum pump.

  According to a preferred embodiment of the present invention, the liquid level reducing device has a pressurized gas supply device for supplying the pressurized gas into the receiving pipe, and an on-off valve provided in the receiving pipe, The position of the on-off valve is between the location where the pressurized gas supply device supplies pressurized gas to the receiving pipe and the storage tank.

  In this configuration, with the on-off valve provided between the pressurized gas supply location and the storage tank closed, the pressurized gas is supplied into the receiving pipe by the pressurized gas supply device, so that the liquid level at the rising portion Can be pushed down.

  According to a preferred embodiment of the present invention, the liquid level reducing device includes a vaporizer that converts the liquefied gas supplied from the storage tank into a vaporized gas, and receives the vaporized gas from the vaporizer as the pressurized gas. Supply in the tube.

  In this configuration, since the vaporized gas from the vaporizer is used as the pressurized gas, a special device for supplying the pressurized gas can be dispensed with. That is, in order to supply the pressurized gas, it is only necessary to provide, for example, a pipe for supplying the vaporized gas to the receiving pipe.

  According to another embodiment of the present invention, the liquid level reducing device includes a vaporized gas pipe for discharging the vaporized gas generated from the liquefied gas in the storage tank to the outside of the storage tank, and the vaporized gas pipe. A compressor provided, and the liquid level reducing device supplies the vaporized gas sent from the compressor into the receiving pipe as the pressurized gas.

  In this configuration, since the vaporized gas from the compressor is used as the pressurized gas, a special device for supplying the pressurized gas can be dispensed with. That is, when the compressor and the vaporized gas pipe are provided in a normal configuration, it is only necessary to provide a pipe for supplying the vaporized gas to the receiving pipe in order to supply the pressurized gas.

  According to a preferred embodiment of the present invention, the liquefied gas receiving and storing device includes a pressure sensor that detects a pressure in a receiving pipe at a predetermined position below the liquid level, and the liquid level based on a pressure value from the pressure sensor. A control device for controlling a reduction device, and the control device determines, based on the pressure value, whether the liquid level has been pushed down to a set height. The liquid level reducing device is controlled to stop the supply of pressurized gas.

  In this configuration, when the control device determines that the height of the liquid level has been pushed down to the set height based on the pressure value, the control device reduces the liquid level reduction device to stop the supply of the pressurized gas. Since it controls, the liquid level height can be controlled to the set height. As a result, the liquid level can be lowered to a height at which the riser portion Geisersing can be avoided.

  According to another embodiment of the present invention, the liquefied gas receiving and storing device includes a liquid level sensor that detects whether the liquid level has reached a set height, and the liquid level pressure reduction based on a signal from the liquid level sensor. A control device for controlling the device, and the control device stops the supply of the pressurized gas when receiving a signal from the liquid level sensor that the liquid level has been pushed down to a set height. The liquid level reduction device is controlled.

  In this configuration, when receiving a signal from the liquid level sensor that the liquid level has been pushed down to a set height, the control unit controls the liquid level reducing apparatus to stop the supply of the pressurized gas. Therefore, the liquid level can be controlled to the set height. As a result, the liquid level can be lowered to a height at which the riser portion Geisersing can be avoided.

  According to the present invention described above, the liquid level at the rising portion can be lowered without using a liquid draining drum and a liquid draining drum pump.

  The best mode for carrying out the present invention will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the common part in each figure, and the overlapping description is abbreviate | omitted.

  FIG. 1 shows a configuration of a liquefied gas receiving and storing device according to an embodiment of the present invention. As shown in FIG. 1, the liquefied gas receiving and storing device 10 includes a storage tank 3, a receiving pipe 5, a liquid level reducing device 7, a pressure sensor 9, and a control device 11. The storage tank 3 is the same as that described with reference to FIG. The receiving pipe 5 is the same as that described with reference to FIG. 4, and has a rising portion 5 a that extends in the vertical direction from the lower side to the upper side while extending to the storage tank 3 side.

  The liquid level reducing device 7 supplies pressurized gas that applies pressure to the liquid level of the rising portion 5a into the receiving pipe 5, thereby pushing down the liquid level. In the example of FIG. 1, the liquid surface pressure reducing device 7 includes a pressurized gas supply device 7a, an on-off valve 7b, and a liquid drain pipe 7c.

  The pressurized gas supply device 7a includes a vaporizer 7a-1 and a pressurized gas supply pipe 7a-2. The vaporizer 7a-1 generates vaporized gas from LNG supplied from the storage tank 3 by the pump 3a. The vaporized gas is sent to a predetermined demand point through the gas supply pipe 13. The pressurized gas supply pipe 7 a-2 is connected to the gas supply pipe 13 and extends to the pressurized gas supply location x of the receiving pipe 5. The pressurized gas supply location x is located downstream from the top of the rising portion 5a and upstream from the location where the receiving pipe 5 is connected to the storage tank 3.

  The on-off valve 7 b is provided in the receiving pipe 5 between the pressurized gas supply point x and the connecting point of the receiving pipe 5 with the storage tank 3.

The liquid drain pipe 7 c allows the receiving pipe 5 and the storage tank 3 to communicate with each other so that LNG pushed back by the pressurized gas is sent to the storage tank 3. In the example of FIG. 1, the drain pipe 7 c extends from the lower part of the rising part 5 a to the top part of the storage tank 3. In addition, an opening / closing valve 15 is provided in the drain pipe 7c.
The drain pipe 7 c joins the LNG return pipe 14 while extending to the storage tank 3. The LNG return pipe 14 branches from the LNG supply pipe extending from the storage tank 3 to the vaporizer 7a-1 and extends to the storage tank 3. The LNG return pipe 14 is provided for cooling piping and equipment other than the receiving pipe 5. Further, as shown in FIG. 1, by providing an orifice 17 at the upstream end of the LNG return pipe 14, a part of the LNG going from the storage tank 3 to the vaporizer 7a-1 is reduced in pressure to reduce the LNG return pipe. 14 to flow.

  The pressure sensor 9 detects the pressure in the receiving pipe 5 at a predetermined position below the liquid level of the rising portion 5a. In the example of FIG. 1, the pressure sensor 9 is provided below the rising portion 5 a in the receiving pipe 5.

  The control device 11 controls the liquid level reducing device 7 based on the pressure value from the pressure sensor 9. Specifically, the control device 11 determines whether the liquid level height of the rising portion 5a has been pushed down to the set height based on the pressure value, and stops the supply of the pressurized gas if it is judged to have been pushed down. In this way, the liquid level reducing device 7 is controlled. The control device 11 includes not only the pressure value detected by the pressure sensor 9 but also the pressure Pa of the pressurized gas, the density ρ of LNG, the internal pressure Pt of the storage tank 3, the rising portion 5a and the drain pipe 7c. The liquid level height of the rising portion 5a can be calculated based on the height h from the connection position to the top of the drain pipe 7c. However, preferably, in order to simplify the configuration of the control device 11, the pressure value output by the pressure sensor 9 when the liquid level of the rising portion 5a is lowered to the set height is set to the pressure Pa of the pressurized gas that is known in advance. The gas stop pressure value is obtained based on the density ρ of LNG, the internal pressure Pt of the storage tank 3, the height h, and the like. Thereby, if the control apparatus 11 judges that the pressure value from the pressure sensor 9 became a gas stop pressure value, it will control the pressurized gas supply apparatus 7a and will stop pressurized gas supply.

The pressure Pa of the above-mentioned pressurized gas should just be larger than Pt + ρgh (Pa> Pt + ρgh).
Pt: Internal pressure ρ of the storage tank 3: LNG density g: Gravitational acceleration h: Height from the connecting position of the rising part 5a and the liquid draining pipe 7c to the top of the liquid draining pipe 7c The above-mentioned pressurized gas supply device 7a is The vaporized gas from the vaporizer 7a-1 is supplied as a pressurized gas. The vaporizer 7a-1 generates a high-pressure vaporized gas, and the pressure of the vaporized gas is sufficiently larger than Pt + ρgh. Therefore, the vaporized gas from the vaporizer 7a-1 can be used as the pressurized gas. When the pressure of the vaporized gas is too high, a pressure reducing valve (not shown) can be provided in the pressurized gas supply pipe 7a-2 to adjust the pressure.

  Next, the operation of the liquefied gas receiving and storing apparatus 10 having the above-described configuration will be described with reference to FIGS.

  When LNG is sent from the liquefied gas supply source (for example, LNG ship) to the storage tank 3 through the receiving pipe 5, and the LNG reception is completed, the LNG remains in the rising portion 5a as shown in FIG. During the LNG reception and at the end of the LNG reception, the on-off valve 7b is open and the on-off valves 15 and 18 are closed.

  In this state, when the on-off valve 7b is closed and the on-off valves 15 and 18 are opened (for example, when an operator operates an operation unit such as the control device 11), the vaporized gas flows into the receiving pipe 5 as pressurized gas, The liquid level of the rising part 5a is pressurized to push down the liquid level. Thereby, as shown in FIG. 2, a liquid level falls.

Subsequently, as shown in FIG. 3, when the control device 11 determines that the pressure value received from the pressure sensor 9 has reached the gas stop pressure value, the liquid level reducing device 7 stops the supply of the pressurized gas. To control. In this example, the control device 11 performs control to send the control signal to the on-off valve 18 and close the on-off valve 18. Thereby, the height of the liquid level of the rising portion 5a becomes the set height.
This set height is set to be higher than the connection location between the receiving pipe 5 and the liquid draining pipe 7c. Thereby, it can avoid that pressurized gas enters the storage tank 3 and the internal pressure of the storage tank 3 rises.

When the above liquid level control is completed, the on-off valve 15 is closed. Then, the LNG remaining in the drain pipe 7c is returned to the storage tank 3 together with the LNG flowing from the LNG return pipe 14 through the check valve 16 to the drain pipe 7c continuously or intermittently as described above. Since the cross-sectional area of the drain pipe 7c is sufficiently smaller than the cross-sectional area of the receiving pipe 5, the drain pipe 7c does not cause a problem of Geiserring.
During the standby period, the LNG in the storage tank 3 is received through a pipe (not shown) (for example, a pipe extending from a midway position of the pipe extending from the storage tank 3 to the vaporizer 7a-1 to a predetermined position of the receiving pipe 5). The receiving pipe 5 can be cooled and held by being intermittently supplied to the inside 5. In this case, the LNG in the receiving pipe 5 may be returned to the storage tank 3 by opening the on-off valve 15. In addition, by supplying LNG from the storage tank 3 to the receiving pipe 5 in this way, when the liquid level of the rising part 5a becomes high, this liquid level can be lowered by the same method as described above.

According to the liquefied gas receiving and storing device 10 according to the above-described embodiment of the present invention, the pressurized gas for applying pressure to the liquid surface of the rising portion 5a is supplied into the receiving pipe 5 by the liquid level reducing device 7, thereby Since the liquid level is pushed down, a liquid draining drum becomes unnecessary.
Further, since LNG pushed back by the pressurized gas is sent to the storage tank 3 through the liquid drain pipe 7c, a liquid drain drum pump is not necessary.
Therefore, the liquid level of the rising portion 5a can be lowered without using the liquid draining drum and the liquid draining drum pump. As a result, it is possible to reduce construction costs and operation costs required for the draining drum and the draining drum pump.

  Further, by supplying the pressurized gas into the receiving pipe 5 by the pressurized gas supply device 7a with the on-off valve 7b provided between the pressurized gas supply point x and the storage tank 3 closed, the rising portion The liquid level of 5a can be pushed down.

  Furthermore, since the vaporized gas from the vaporizer 7a-1 is used as the pressurized gas, a special device for supplying the pressurized gas can be dispensed with. In other words, in order to supply the pressurized gas, it is only necessary to provide a pipe, for example.

  Further, when the control device 11 determines that the liquid level is pushed down to the set height based on the pressure value from the pressure sensor 9, the control device 11 controls the liquid level reducing device 7 to stop the supply of the pressurized gas. Therefore, the liquid level can be controlled to the set height. Thereby, a liquid level can be lowered | hung to the height which can avoid the Geiser ring of the standup | rising part 5a.

  The present invention is not limited to the above-described embodiment, and various changes can be made without departing from the scope of the present invention.

For example, in the above embodiment, the pressurized gas supply device 7a supplies the vaporized gas from the vaporizer 7a-1, but the present invention is not limited to this. That is, a pressurized gas supply source independent of the vaporizer may be provided as the pressurized gas supply device without using the vaporized gas from the vaporizer.
For example, as shown in FIG. 4, the liquid level reduction device 7 is configured to store the vaporized gas (in this example, BOG) generated from the liquefied gas (in this example, LNG) by heat input to the storage tank 3 in the storage tank 3. 3 has a vaporized gas pipe 19a (in this example, a BOG pipe 19a) and a compressor 19b (in this example, a BOG compressor 19b) provided in the vaporized gas pipe 19a. The liquid level reducing device 7 supplies the vaporized gas sent from the compressor 19b as the pressurized gas into the receiving pipe 5 at the pressurized gas supply point x. In the example of FIG. 4, the BOG pipe 19 a extends from the storage tank 3 to the gas feed pipe 13 so that the compressed BOG from the BOG compressor 19 b joins the gas feed pipe 13. In the example of FIG. 4, the pressurized gas supply pipe 7a-2 extends from a midway position of the BOG pipe 19a on the downstream side of the BOG compressor 19b and upstream of the check valve 19c to the pressurized gas supply position x. .

Moreover, you may provide the liquid level sensor which detects whether the liquid level of the rising part 5a became the setting height instead of the said pressure sensor. In this case, the control device 11 controls the liquid level reducing device 7 based on a signal from the liquid level sensor. That is, when receiving a signal from the liquid level sensor that the liquid level of the rising portion 5a has been pushed down to the set height, the control device 11 stops the supply of the pressurized gas as in the above-described embodiment. The reduction device 7 is controlled.
The liquid level sensor may use a thermistor, for example. In this case, when the liquid level sensor is fixed at the set height of the rising portion 5a in the receiving pipe 5, and the liquid level of the rising portion 5a is positioned below the position of the thermistor (that is, the set height), The temperature of the thermistor rises as the thermistor exits from the liquid into the gas. As a result, the electrical resistance value of the thermistor changes, and this change is sent as an electrical signal to the control device 11, and the electrical signal is received (as a signal that the liquid level of the rising portion 5a has been pushed down to the set height). The control device 11 controls the liquid level reducing device 7 so as to stop the supply of the pressurized gas. In addition, a liquid level sensor is not limited to this, Another liquid level sensor can also be used.

  In the above embodiment, the liquefied gas receiving and storing device receives and stores LNG. However, the liquefied gas receiving and storing device may receive and store other liquefied gas such as LPG.

It is a block diagram of the liquefied gas receiving and storing apparatus by embodiment of this invention. It is a figure which shows the state which is pushing down the liquid level. It is a figure which shows the state which the pressing down of the liquid level was completed. It is a block diagram of the liquefied gas reception storage apparatus by another embodiment of this invention. It is a block diagram of LNG receiving equipment. It is a block diagram for performing the liquefied gas holding and replacement method.

Explanation of symbols

3 storage tank, 3a pump, 5 receiving pipe, 5a riser,
7 liquid level reduction device, 7a pressurized gas supply device, 7a-1 vaporizer,
7a-2 Pressurized gas supply pipe, 7b On-off valve, 7c Drain pipe,
9 pressure sensor, 10 liquefied gas receiving storage device, 11 control device,
13 gas supply pipe, 14 LNG return pipe, 15 on-off valve,
16 check valve, 17 orifice, 19a vaporized gas pipe (BOG pipe),
19b Compressor (BOG compressor), 19c Check valve

Claims (7)

A storage tank for receiving and storing the liquefied gas from a predetermined liquefied gas supply source, and a receiving pipe for sending the liquefied gas from the liquefied gas supply source to the storage tank, and at the end of receiving the liquefied gas into the storage tank A liquefied gas receiving and storing device having a function of controlling the height of the liquid level of the liquefied gas remaining in the receiving pipe,
The receiving pipe has a rising portion extending upward from below in the middle of extending to the storage tank side,
The liquid level is the level of the liquefied gas remaining at the rising portion,
A liquefied gas receiving and storing device, comprising: a pressure level reducing device that supplies pressurized gas for applying pressure to the liquid level into the receiving pipe, thereby depressing the liquid level.   2. The liquefied gas according to claim 1, wherein the liquid surface pressure reducing device includes a liquid drain pipe that connects the receiving pipe and the storage tank so as to send the liquefied gas pushed back by the pressurized gas to the storage tank. Receiving storage device. The liquid level reduction device is:
A pressurized gas supply device for supplying the pressurized gas into a receiving pipe;
An on-off valve provided in the receiving pipe,
The liquefied gas receiving storage according to claim 1, wherein the position of the on-off valve in the receiving pipe is between a storage tank and a location where the pressurized gas supply device supplies the pressurized gas to the receiving pipe. apparatus.   The liquid surface pressure reducing device has a vaporizer that converts the liquefied gas supplied from the storage tank into a vaporized gas, and supplies the vaporized gas from the vaporizer as the pressurized gas into the receiving pipe. The liquefied gas receiving and storing device according to claim 1. The liquid surface pressure reducing device has a vaporized gas pipe for discharging vaporized gas generated from the liquefied gas in the storage tank to the outside of the storage tank, and a compressor provided in the vaporized gas pipe,
The liquefied gas receiving and storing device according to claim 1, wherein the liquid level reducing device supplies the vaporized gas delivered from the compressor into the receiving pipe as the pressurized gas. A pressure sensor for detecting the pressure in the receiving pipe at a predetermined position below the liquid level;
A control device for controlling the liquid level reduction device based on a pressure value from the pressure sensor,
The control device determines whether the liquid level has been pushed down to a set height based on the pressure value, and determines that the liquid level has been lowered so as to stop the supply of the pressurized gas if it has been pushed down. The apparatus for receiving and storing liquefied gas according to claim 1, wherein the apparatus is controlled. A liquid level sensor for detecting whether the liquid level has reached a set height;
A control device for controlling the liquid level reduction device based on a signal from the liquid level sensor,
When the control device receives a signal from the liquid level sensor that the liquid level has been pushed down to a set height, the control device controls the liquid level reduction device to stop the supply of the pressurized gas. The liquefied gas receiving and storing apparatus according to claim 1.

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